JP4976181B2 - Tip placement method for throw-away drills - Google Patents

Tip placement method for throw-away drills Download PDF

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Publication number
JP4976181B2
JP4976181B2 JP2007098150A JP2007098150A JP4976181B2 JP 4976181 B2 JP4976181 B2 JP 4976181B2 JP 2007098150 A JP2007098150 A JP 2007098150A JP 2007098150 A JP2007098150 A JP 2007098150A JP 4976181 B2 JP4976181 B2 JP 4976181B2
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drill
throw
diameter
cutting
blade
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JP2008178967A (en
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和親 那須
敦彦 前田
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Sumitomo Electric Hardmetal Corp
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Sumitomo Electric Hardmetal Corp
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Priority to JP2007098150A priority Critical patent/JP4976181B2/en
Application filed by Sumitomo Electric Hardmetal Corp filed Critical Sumitomo Electric Hardmetal Corp
Priority to US12/520,338 priority patent/US8388278B2/en
Priority to PCT/JP2007/074700 priority patent/WO2008078696A1/en
Priority to ES07851052.6T priority patent/ES2453366T3/en
Priority to CN2007800451269A priority patent/CN101547763B/en
Priority to EP07851052.6A priority patent/EP2098319B1/en
Publication of JP2008178967A publication Critical patent/JP2008178967A/en
Priority to IL199432A priority patent/IL199432A/en
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    • BPERFORMING OPERATIONS; TRANSPORTING
    • B23MACHINE TOOLS; METAL-WORKING NOT OTHERWISE PROVIDED FOR
    • B23BTURNING; BORING
    • B23B51/00Tools for drilling machines
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B23MACHINE TOOLS; METAL-WORKING NOT OTHERWISE PROVIDED FOR
    • B23BTURNING; BORING
    • B23B2200/00Details of cutting inserts
    • B23B2200/20Top or side views of the cutting edge
    • B23B2200/201Details of the nose radius and immediately surrounding area
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B23MACHINE TOOLS; METAL-WORKING NOT OTHERWISE PROVIDED FOR
    • B23BTURNING; BORING
    • B23B2251/00Details of tools for drilling machines
    • B23B2251/14Configuration of the cutting part, i.e. the main cutting edges
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B23MACHINE TOOLS; METAL-WORKING NOT OTHERWISE PROVIDED FOR
    • B23BTURNING; BORING
    • B23B2251/00Details of tools for drilling machines
    • B23B2251/18Configuration of the drill point
    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y10TECHNICAL SUBJECTS COVERED BY FORMER USPC
    • Y10TTECHNICAL SUBJECTS COVERED BY FORMER US CLASSIFICATION
    • Y10T408/00Cutting by use of rotating axially moving tool
    • Y10T408/03Processes
    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y10TECHNICAL SUBJECTS COVERED BY FORMER USPC
    • Y10TTECHNICAL SUBJECTS COVERED BY FORMER US CLASSIFICATION
    • Y10T408/00Cutting by use of rotating axially moving tool
    • Y10T408/86Tool-support with means to permit positioning of the Tool relative to support
    • Y10T408/87Tool having stepped cutting edges
    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y10TECHNICAL SUBJECTS COVERED BY FORMER USPC
    • Y10TTECHNICAL SUBJECTS COVERED BY FORMER US CLASSIFICATION
    • Y10T408/00Cutting by use of rotating axially moving tool
    • Y10T408/89Tool or Tool with support
    • Y10T408/899Having inversely angled cutting edge
    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y10TECHNICAL SUBJECTS COVERED BY FORMER USPC
    • Y10TTECHNICAL SUBJECTS COVERED BY FORMER US CLASSIFICATION
    • Y10T408/00Cutting by use of rotating axially moving tool
    • Y10T408/89Tool or Tool with support
    • Y10T408/905Having stepped cutting edges
    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y10TECHNICAL SUBJECTS COVERED BY FORMER USPC
    • Y10TTECHNICAL SUBJECTS COVERED BY FORMER US CLASSIFICATION
    • Y10T408/00Cutting by use of rotating axially moving tool
    • Y10T408/89Tool or Tool with support
    • Y10T408/905Having stepped cutting edges
    • Y10T408/906Axially spaced
    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y10TECHNICAL SUBJECTS COVERED BY FORMER USPC
    • Y10TTECHNICAL SUBJECTS COVERED BY FORMER US CLASSIFICATION
    • Y10T408/00Cutting by use of rotating axially moving tool
    • Y10T408/89Tool or Tool with support
    • Y10T408/909Having peripherally spaced cutting edges
    • Y10T408/9095Having peripherally spaced cutting edges with axially extending relief channel
    • Y10T408/9097Spiral channel

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  • Engineering & Computer Science (AREA)
  • Mechanical Engineering (AREA)
  • Drilling Tools (AREA)

Description

この発明は、切れ刃が複数個のスローアウェイチップで構成されるスローアウェイドリル、詳しくは、切削性能が安定し、穴出口のばりの発生も抑制されるスローアウェイドリルの安定した切削性能をドリル径変更後も維持可能となすチップ配置方法に関する。 The present invention, indexable drills configured cutting edges of a plurality of indexable inserts, particularly, the cutting performance is stable, cutting performance was cheap boss of throwaway drill that generation of burrs in the hole exit is suppressed It is related with the chip | tip arrangement method which makes it possible to maintain after drill diameter change.

金属の穴あけに用いるスローアウェイドリルの中に、下記特許文献1、2などに開示されたものや、図16、図17に示すようなものがある。   Among throw-away drills used for drilling metal, there are those disclosed in Patent Documents 1 and 2 below, and those shown in FIGS. 16 and 17.

これらのドリルは、中心にクランプ穴を有する板状スローアウェイチップ5(符号は図16、図17を参照)を2個組み合わせて使用し、そのスローアウェイチップ5をドリル本体1の先端にドリル中心からの設置距離を異ならせて、かつ、設置点の位相をドリル周方向に180°異ならせて配置し、ドリル内径側に配置されるスローアウェイチップで中心刃8を、ドリル外径側に配置されるスローアウェイチップで外周刃9をそれぞれ形成している。   These drills use a combination of two plate-shaped throw-away tips 5 (refer to FIGS. 16 and 17) having a clamp hole at the center, and the throw-away tip 5 is attached to the tip of the drill body 1 at the center of the drill. With different installation distances from each other and with the phase of the installation point 180 ° different in the circumferential direction of the drill, the center blade 8 is arranged on the outer diameter side of the drill with a throw-away tip arranged on the inner diameter side of the drill Each of the outer peripheral blades 9 is formed by a throwaway tip to be formed.

この種のドリルは、同一仕様のスローアウェイチップを使用してドリル径を変更する場合(外径の異なるドリルを作る場合)、図18に示すように、中心刃8を固定し、外周刃9を径方向に移動させてドリル径(図の1/2Dはドリル半径を表す)を変化させる方法が一般的に採られている。   In this type of drill, when the drill diameter is changed using a throw-away tip having the same specification (when making a drill having a different outer diameter), as shown in FIG. Generally, a method of changing the drill diameter (1 / 2D in the figure represents the drill radius) by moving the diameter in the radial direction is employed.

また、各刃のワークに対する食いつきは、中心刃8の中央部や外周刃9の中央部からなされるようにするのが一般的である。
特許第2704917号公報 特開平11−235606号公報
Further, the biting of each blade with respect to the work is generally performed from the central portion of the central blade 8 or the central portion of the outer peripheral blade 9.
Japanese Patent No. 27041717 JP-A-11-235606

特許文献1が開示しているような従来のスローアウェイドリルは、ワークに対する食いつきが中心刃や外周刃の中央部から起こるため、食いつき時の切削抵抗(水平分力)が安定せず、これが原因で加工穴の食いつき側では入口穴径のばらつき、面粗度の悪化などの問題が発生する。また、貫通穴加工の場合、穴貫通時の切削バランスが悪化し、出口穴径のばらつきや面粗度悪化などの問題も発生する。穴貫通時に外径側の切り抜けが遅れて外径側から内側に向かって押す力が働くため、穴出口側では穴径が縮小傾向となり、そのドリルを加工した穴から引き抜くときに、穴の内面にいわゆる戻りマークがつきやすい。これに加えて、穴貫通時にばりが発生し易い。外径側の切り抜けが遅れることによって切り抜けが遅れた位置に薄くて切れ難い肉が残り、それが切り残されてワークWに加工された穴11出口の縁に図19に示すようなばり12が発生する。   In the conventional throw-away drill as disclosed in Patent Document 1, since the biting on the workpiece occurs from the center part of the center blade or the outer peripheral blade, the cutting resistance (horizontal component force) at the time of biting is not stable, and this is the cause. On the biting side of the processed hole, problems such as variations in inlet hole diameter and deterioration of surface roughness occur. Further, in the case of through hole machining, the cutting balance at the time of hole penetration deteriorates, and problems such as variations in outlet hole diameter and deterioration of surface roughness also occur. When the hole is penetrated, the outer diameter side cut-out is delayed and a pressing force works from the outer diameter side to the inner side.Therefore, the hole diameter tends to decrease on the hole outlet side, and when the drill is pulled out from the processed hole, It is easy to put a so-called return mark. In addition to this, flash is likely to occur when the hole is penetrated. A thin and difficult-to-cut meat remains at the position where the cut-out is delayed due to a delay in the cutout on the outer diameter side, and a flash 12 as shown in FIG. appear.

また、上記の従来法によるドリル径変更では、中心刃が固定され、外周刃のみが径方向に移動する。そのために、中心刃と外周刃の切削負担率(図18のA:B)が外周刃の移動の前後において変化し、これに伴う切削バランスの変動によってドリル性能(加工穴径や切削抵抗など)のばらつきが起こる。   Moreover, in the drill diameter change by said conventional method, a center blade is fixed and only an outer peripheral blade moves to radial direction. Therefore, the cutting burden rate (A: B in FIG. 18) of the center blade and the outer peripheral blade changes before and after the movement of the outer peripheral blade, and the drill performance (such as the drilling hole diameter and cutting resistance) due to the fluctuation of the cutting balance accompanying this change. Variations occur.

この発明は、切れ刃が複数個のスローアウェイチップで構成されるスローアウェイドリルを、安定した性能が発揮されて入口穴径、出口穴径の精度が向上し、穴出口のばりの発生も抑制されるようにすること、及び、ドリル径変更後も安定した切削性能が維持されるようにすることを課題としている。   This invention is a throw-away drill consisting of a plurality of throw-away inserts, with stable performance, improving the accuracy of the inlet hole diameter and outlet hole diameter, and suppressing the occurrence of burr at the hole outlet. It is an object to make it possible to maintain the stable cutting performance even after changing the drill diameter.

上記の課題を解決するため、この発明においては、ドリル径を変更したときの切削性能の変動をなくするために、ドリル本体の先端のドリル周方向に半周した位置に第1、第2の2個のスローアウェイチップをドリル中心からの設置距離を異ならせて配置し、
ドリル外径側に配置される第2スローアウェイチップをドリル内径側に配置される第1
スローアウェイチップよりも軸方向前方に突出させてワークに対する食いつきが第2スローアウェイチップの外端コーナ部から起こるようにし、さらに、前記第1スローアウェイチップによって形成される中心刃の切削負担量Aと第2スローアウェイチップによって形成される外周刃の切削負担量Bの割合をA:B=52:48〜55:45の範囲に設定し、
以上の構成としたスローアウェイドリルの外径を変更する際に、第2スローアウェイチップと第1スローアウェイチップの位置を共に変化させて前記中心刃と外周刃の切削負担量の比率A:B=52:48〜55:45をドリル径変更後も維持するチップ配置方法を提供する。
In order to solve the above-described problems, in the present invention, in order to eliminate fluctuations in the cutting performance when the drill diameter is changed, the first and second 2 are located at positions where the tip of the drill body is half-circulated in the drill circumferential direction. Place one throwaway tip with a different installation distance from the center of the drill,
The first throw-away tip disposed on the drill outer diameter side is the first disposed on the drill inner diameter side.
The workpiece is made to project forward in the axial direction from the throw-away tip so that the workpiece bites from the outer end corner portion of the second throw-away tip, and the cutting load A of the center blade formed by the first throw-away tip A And the ratio of the cutting burden amount B of the outer peripheral blade formed by the second throw-away tip is set in a range of A: B = 52: 48 to 55:45,
When changing the outer diameter of the throw-away drill having the above-described configuration, the positions of the second throw-away tip and the first throw-away tip are changed to change the ratio A: B of the cutting burden amount between the central blade and the outer peripheral blade. = 52: 48 to 55: 45 to provide a chip arrangement how to maintain even after a drill diameter changing.

この発明のチップ配置方法によれば、ドリル径が変わっても中心刃と外周刃の切削負担量の割合が変更前と同じ値に維持されるので、切削負担量の割合の変動に起因した性能変化が防止され、ドリル径変更後も安定した切削性能が発揮されて加工穴精度のばらつきが抑制される。According to the chip arrangement method of the present invention, even if the drill diameter is changed, the ratio of the cutting burden of the center blade and the outer peripheral blade is maintained at the same value as before the change, so the performance due to the fluctuation of the ratio of the cutting burden The change is prevented, stable cutting performance is exhibited even after the drill diameter is changed, and variations in the machined hole accuracy are suppressed.

また、第1スローアウェイチップで中心刃を、第2スローアウェイチップで外周刃をそれぞれ形成し、中心刃の切削負担量Aと外周刃の切削負担量Bの割合をA:B=52:48〜55:45の範囲に設定したので、切削時のスラスト、水平分力が小さく抑えられて切削の安定性が高まる。 Further, the central blade is formed with the first throw-away tip and the outer peripheral blade is formed with the second throw-away tip, and the ratio of the cutting burden amount A of the central blade to the cutting burden amount B of the outer peripheral blade is A: B = 52: 48. 55: since the set in a range of 45, the thrust during cutting, stable cutting and horizontal force is kept small high circle.

また、同一仕様の平行四辺形のチップを採用してそのチップの長辺の稜線と短辺の稜線で中心刃と外周刃をそれぞれ形成するものは、使用するスローアウェイチップの種類が統合されて経済効果が高まる。   In addition, when the parallelogram insert of the same specification is adopted and the center edge and the outer periphery edge are respectively formed by the long edge and the short edge of the chip, the types of throw-away inserts used are integrated. Economic effect increases.

以下、この発明の実施の形態を、添付図面の図1〜図6に基づいて説明する。図1〜図5は、この発明を適用するスローアウェイドリルの具体例を示している。このドリル10は、ドリル本体1と、そのドリル本体の先端外周に装着する2個のスローアウェイチップ5−1,5−2(付加記号の−1−2は区別の便宜上付した)と、各スローアウェイチップ5−1,5−2をドリル本体1に着脱自在に固定するクランプねじ7とで構成されている。 Embodiments of the present invention will be described below with reference to FIGS. 1 to 6 of the accompanying drawings. 1 to 5 show specific examples of a throw-away drill to which the present invention is applied . The drill 10 includes a drill body 1 and two throwaway tips 5 -1 and 5 -2 attached to the outer periphery of the tip of the drill body (additional symbols -1 and -2 are attached for the sake of distinction), Each of the throwaway tips 5 -1 and 5-2 is composed of a clamp screw 7 that detachably fixes to the drill body 1.

ドリル本体1は、外周に切屑排出用の2条の溝2を有し、さらに、先端のドリル周方向に半周した位置にチップ座3,3を有する。溝2はストレート溝も考えられるが、例示のドリルではねじれ溝を採用しており、また、チップ座3,3は、回転中心Oからの距離を異ならせた位置に設けられている。   The drill body 1 has two grooves 2 for discharging chips on the outer periphery, and further has chip seats 3 and 3 at a position half-circulated in the drill circumferential direction at the tip. The groove 2 may be a straight groove, but the illustrated drill employs a twisted groove, and the tip seats 3 and 3 are provided at different positions from the rotation center O.

スローアウェイチップ5−1,5−2は、中心にクランプ穴6を設けた平行四辺形のチップであり、同一仕様(同一形状、同一寸法)のチップが採用されている。この2個のスローアウェイチップ5−1,5−2が、ドリル本体1の先端に設けたチップ座3,3に装着され、クランプねじ7によってドリル本体1に固定されている。 The throw-away tips 5 -1 and 5-2 are parallelogram tips having a clamp hole 6 at the center, and tips having the same specifications (same shape and same dimensions) are employed. The two indexable inserts 5 -1 and 5 -2 are attached to the tip seat 3 and 3 provided at the tip of the drill body 1, and is fixed to the drill body 1 by a clamping screw 7.

一方のスローアウェイチップ(第1スローアウェイチップ)5−1は、ドリル本体1の中心側に回転中心Oを越える状態に配置されており、このチップ5−1の鈍角コーナのひとつを含む長辺の稜線によってドリルの中心刃8が形成されている。また、他方のスローアウェイチップ(第2スローアウェイチップ)5−2はドリル本体1の外周部に配置されており、このチップ5−2の鋭角コーナのひとつを含む短辺の稜線によってドリルの外周刃9が形成されている。 One indexable insert (first indexable insert) 5-1 is disposed in a state exceeding the rotation center O to the center side of the drill body 1, the long sides including the one obtuse corner of the chip 5 -1 The center edge 8 of the drill is formed by the ridgeline. The other indexable insert (second indexable insert) 5-2 is disposed on the outer periphery of the drill main body 1, the outer periphery of the drill by ridgeline of a short side including one of acute corners of the chip 5-2 A blade 9 is formed.

その中心刃8と外周刃9は、図1、図2に示すように、共に径方向外端側が軸方向前方に突出する方向に傾いた刃として形成されて図4に示すように、外周刃9が中心刃8よりも軸方向前方にh突出するように配置されており、そのために、ワークに対するドリルの食いつきと貫通穴加工時のドリルの切り抜けが共に外周刃9の外端コーナ部9aの位置から起こる。それによって、食いつき当初の水平分力の変動が小さくなり、切削バランスの崩れが抑制されて入口穴精度のばらつきが抑制される。また、貫通穴の加工では、穴の外径側が先に切り抜けるため、出口穴径の縮小傾向がなくなり、ばりも発生し難くなる。なお、中心刃8に対する外周刃9の突出量hは、外周刃9の外端コーナ部9aがワークに食いついてからドリルが1回転するまでの間に中心刃8がワークに食いつくように設定すると食いつき当初の回転バランスの崩れが起こり難い。その突出量hは、ドリルの使用時の送り量を考慮して適正な値に設定するとよい。   As shown in FIGS. 1 and 2, the center blade 8 and the outer peripheral blade 9 are both formed as blades inclined in a direction in which the radially outer end side protrudes forward in the axial direction, and as shown in FIG. 9 is disposed so as to protrude forward in the axial direction from the center blade 8, and therefore, the biting of the drill with respect to the workpiece and the drilling of the drill at the time of drilling the through hole are both in the outer end corner portion 9 a of the outer peripheral blade 9. Arises from position. As a result, the fluctuation of the horizontal component force at the beginning of biting is reduced, the disruption of the cutting balance is suppressed, and the variation in the inlet hole accuracy is suppressed. Further, in the processing of the through hole, since the outer diameter side of the hole is cut through first, the outlet hole diameter does not tend to be reduced, and burrs are hardly generated. The protrusion amount h of the outer peripheral blade 9 with respect to the central blade 8 is set so that the central blade 8 bites the workpiece after the outer end corner portion 9a of the outer peripheral blade 9 bites the workpiece until the drill rotates once. The initial rotation balance is unlikely to break. The protrusion amount h may be set to an appropriate value in consideration of the feed amount when the drill is used.

図6に示す中心刃8の切削負担量Aは外周刃9の切削負担量Bよりも大きい。図6の1/2Dはドリル半径を表す。中心刃8の切削負担量Aと外周刃9の切削負担量Bの割合は、A:B=52:48〜55:45の範囲に設定されており、この割合は、ドリル径に関係なく固定され、ドリル径を変更するとき(同一仕様のチップを使用して外径の異なるドリルを作るとき)にも同一割合での設定がなされる。   The cutting burden amount A of the center blade 8 shown in FIG. 6 is larger than the cutting burden amount B of the outer peripheral blade 9. In FIG. 6, 1 / 2D represents the drill radius. The ratio of the cutting burden amount A of the central blade 8 and the cutting burden amount B of the outer peripheral blade 9 is set in a range of A: B = 52: 48 to 55:45, and this ratio is fixed regardless of the drill diameter. Even when the drill diameter is changed (when drills having different outer diameters are made using the same specification tip), the same ratio is set.

ドリル径の変更は、中心刃8と外周刃9を形成するスローアウェイチップ5−1,5−2の相対位置を、図6(a)から図6(b)のように、或いは図6(b)から図6(a)のように変化させて変更し、そのときに各刃の切削負担量A、Bの比率がドリル径変更後も維持される位置にスローアウェイチップを配置する方法でなされる。図6(a)、(b)のように、外周刃9だけでなく中心刃8の固定位置も変えるようにすることで、ドリル径の選択範囲を広げることができる。 Changing the drill diameter, indexable inserts 5 -1 forming the center cutting edge 8 and the peripheral cutting edge 9, the relative position of 5-2, as shown in FIG. 6 (b) from FIG. 6 (a), or 6 ( By changing from b) to FIG. 6 (a), the throw away tip is arranged at a position where the ratio of the cutting burdens A and B of each blade is maintained even after the drill diameter is changed. Made. As shown in FIGS. 6A and 6B, the selection range of the drill diameter can be widened by changing not only the outer peripheral blade 9 but also the fixing position of the central blade 8.

設置点を変更した2個のスローアウェイチップ5−1,5−2を、ドリル本体(これは径変更前のドリル本体とは仕様が異なる)に装着して外径の異なるドリルを作成する。そのドリルは、中心刃の切削負担量Aと外周刃の切削負担量Bの割合がドリル径を変更する前と同じになるように設定されているので、切削負担量の割合の変化に起因した切削性能の変動は起こらない。 The two throwaway tips 5 -1 and 5 -2 whose installation points are changed are mounted on a drill body (which has different specifications from the drill body before the diameter change) to create a drill having a different outer diameter. The drill was set so that the ratio of the cutting burden amount A of the center blade and the cutting burden amount B of the outer peripheral blade was the same as before the drill diameter was changed, and this was caused by the change in the ratio of the cutting burden amount. Variations in cutting performance do not occur.

図6のように、中心刃8と外周刃9として同一仕様の平行四辺形のスローアウェイチップを使用する場合、切削負担量の大きい中心刃8に長辺の稜線を、切削負担量の小さい外周刃9に短辺の稜線を各々割り当てるとよい。これにより、径の異なるドリルに対して、同一仕様のスローアウェイチップを対応させることが可能になる。このときのスローアウェイチップの形状は、短辺の稜線の長さに対して長辺の稜線の長さを1.1倍程度にすると、中心刃と外周刃の最適長さの比率を保ちつつ幅広く径展開を行なうことができて好ましい。   As shown in FIG. 6, when the parallelogram throw-away tip having the same specification is used as the center blade 8 and the outer peripheral blade 9, a long edge is formed on the central blade 8 having a large cutting burden and the outer periphery having a small cutting burden. It is preferable to assign a short-side ridge line to each of the blades 9. Thereby, it becomes possible to make the throw-away tip of the same specification correspond to a drill with a different diameter. The shape of the throw-away tip at this time is such that when the length of the long side ridge line is about 1.1 times the length of the short side ridge line, the ratio of the optimum length of the center blade and the outer peripheral blade is maintained. It is preferable because the diameter can be expanded widely.

例示のドリル10の切屑排出用の溝2(ねじれ溝)は、ドリル本体1の周囲をほぼ1/4周する溝にし、図5(a)のドリル端面視において、各ねじれ溝の終端の切れ上がり開始点2a(その開始点の溝幅方向中心点)を、外周刃9から周方向にα=85〜95°回転した位置に設定してあり、そのために、ドリル本体1の2箇所のランド部4の終端がドリルの正面視においてチップ設置部のドリル軸方向後方、すなわち、穴加工時に水平分力が作用する方向の両側に位置してその位置にドリル本体の肉が残され、これにより、ドリル本体1の根元側の水平分力に耐える方向の強度が確保され、水平分力によるドリル本体の振れが小さく抑えられる。   The chip discharging groove 2 (twisted groove) of the drill 10 shown in FIG. 5 is a groove that makes a quarter of the circumference of the drill body 1, and the end of each twisted groove is cut in the end view of the drill in FIG. The rising start point 2a (the center point in the groove width direction of the start point) is set to a position rotated by α = 85 to 95 ° in the circumferential direction from the outer peripheral blade 9, and for that purpose, two lands on the drill body 1 are provided. The end of the portion 4 is located behind the tip installation portion in the drill axis direction in the front view of the drill, that is, on both sides in the direction in which the horizontal component force acts when drilling, and the meat of the drill body is left in that position. The strength in the direction to withstand the horizontal component force on the base side of the drill body 1 is ensured, and the deflection of the drill body due to the horizontal component force is kept small.

なお、例示のドリル10は、中心刃8と外周刃9の回転中心と直角な線に対する傾き角θ(図1、図2参照)を共に5°としたが、この角度は外周刃の半径方向すかし角β(図6(a)参照)が0°とならない範囲で任意に設定することができる。   In the illustrated drill 10, the inclination angle θ (see FIGS. 1 and 2) with respect to a line perpendicular to the rotation center of the center blade 8 and the outer peripheral blade 9 is set to 5 °, but this angle is the radial direction of the outer peripheral blade. The watermark angle β (see FIG. 6A) can be arbitrarily set within a range that does not become 0 °.

また、中心刃8の半径方向すくい角γ1を−5°、外周刃9の半径方向すくい角γ2、
を+5°に設定したが、その半径方向すくい角は切れ味やチップの耐久性に支障の出ない範囲で任意に変更してよい。
Also, the radial rake angle γ1 of the central blade 8 is −5 °, the radial rake angle γ2 of the outer peripheral blade 9 is
Is set to + 5 °, but the rake angle in the radial direction may be arbitrarily changed as long as the sharpness and the durability of the chip are not hindered.

さらに、中心刃8は、直線である必要はなく、例えば、径方向途中が軸方向前方に突き出す山形の刃などであってもよい。   Furthermore, the center blade 8 does not need to be a straight line, and may be, for example, a chevron blade protruding in the axial direction forward in the radial direction.

このほか、スペース的な問題がなければスローアウェイチップを3個、或いはそれ以上組み合わせて切れ刃を構成しても構わない。 In addition, three of the throw-away tip if there is no space problems, or it is also possible to configure the cutting edges in combination more.

−実施例1−
中心刃の切削負担量Aと外周刃9の切削負担量Bの割合を、A:B=52:48〜55:45としてドリル径を変更するときにもその割合を維持することの有効性を確認するために、直径D=18.5mm、20.0mm、22.5mmの3種類のドリル(いずれも図1〜図5に示す形状)を使用して以下の実験を行った。
実験は、各ドリルについて、外周刃に対する中心刃の切削負担量の割合を50%にした試料I、52.5%にした試料II、55.0%にした試料IIIをそれぞれ準備し、以下の条件で穴あけを行ってそのときのスラストと水平分力を、キスラー動力計を使用して測定した。また、送りを変えたときのドリル径の実測値と加工された穴の入口径、中間径(深さ方向中間点の径)、出口径をそれぞれ求めた。
−切削条件−
ワーク材質:S50C
切削速度V=175m/min
送りf=0.08mm/rev及びf=0.15mm/rev
湿式切削
Example 1
The ratio of the cutting burden amount A of the central blade and the cutting burden amount B of the outer peripheral blade 9 is set to A: B = 52: 48 to 55:45. In order to confirm, the following experiment was performed using three types of drills (all of the shapes shown in FIGS. 1 to 5) having a diameter D = 18.5 mm, 20.0 mm, and 22.5 mm.
In the experiment, for each drill, a sample I in which the ratio of the cutting burden amount of the central blade to the outer peripheral blade was 50%, a sample II in 52.5%, and a sample III in 55.0% were prepared. Drilling was performed under the conditions, and the thrust and horizontal component force at that time were measured using a Kistler dynamometer. In addition, the measured value of the drill diameter when the feed was changed, the inlet diameter of the processed hole, the intermediate diameter (diameter at the midpoint in the depth direction), and the outlet diameter were determined.
-Cutting conditions-
Work material: S50C
Cutting speed V = 175 m / min
Feed f = 0.08mm / rev and f = 0.15mm / rev
Wet cutting

この試験の結果を、図7〜図12に示す。図7〜図9は、試料I〜IIIに関するf=0.08mm/revのときとf=0.15mm/revのときのスラストSと水平分力Fを表している。
また、図10〜図12は、試料I〜IIIに関するf=0.08mm/revのときとf=0.15mm/revのときのドリル径の実測値と加工された穴の径をそれぞれ表している。
The results of this test are shown in FIGS. FIGS. 7 to 9 show the thrust S and the horizontal component force F for the samples I to III when f = 0.08 mm / rev and when f = 0.15 mm / rev.
FIGS. 10 to 12 show the measured values of the drill diameter and the diameter of the processed holes when f = 0.08 mm / rev and f = 0.15 mm / rev for samples I to III, respectively. Yes.

図7〜図9のデータからわかるように、中心刃の切削負担量Aの割合を52.5%にした試料IIは、Aの値を50.0%にした試料Iや55.0%にした試料IIIに比べてスラストSと水平分力Fが明らかに小さくて安定している。また、試料IIは、図10〜図12のデータからわかるように、送り量変更に伴うトルク変動に対して送り量変更前後の穴径の変化の傾向も近似しており、試料I、IIIよりも切削性能が安定していることがわかる。   As can be seen from the data in FIG. 7 to FIG. 9, Sample II in which the ratio of the cutting burden amount A of the center blade is 52.5% is Sample I in which the value of A is 50.0% and 55.0%. The thrust S and the horizontal component force F are clearly smaller and more stable than the sample III. In addition, as can be seen from the data in FIGS. 10 to 12, sample II also approximates the tendency of hole diameter change before and after the feed amount change with respect to the torque fluctuation accompanying the feed amount change. It can also be seen that the cutting performance is stable.

−実施例2−
直径D=20mmの図1〜図5に示す形状のドリル(発明適用品)と、同一外径の比較ドリル(住友電工ハードメタル社製 WDS200M3S25 その刃先形状は図13を参照)を使用して以下の条件で穴あけを行い、この実験における食いつき時の水平分力X、Yをキスラー動力計で測定した。
−切削条件−
ワーク材質:SCM415
切削速度V=130m/min
送りf=0.10mm/rev
加工穴:深さd=50mmの貫通穴
湿式切削
-Example 2-
1 to 5 with a diameter D = 20 mm (invention applied product) and a comparison drill with the same outer diameter (WDS200M3S25 manufactured by Sumitomo Electric Hardmetal Co., Ltd., see FIG. 13 for the cutting edge shape) In this experiment, the horizontal component forces X and Y at the time of biting were measured with a Kistler dynamometer.
-Cutting conditions-
Work material: SCM415
Cutting speed V = 130 m / min
Feed f = 0.10mm / rev
Hole: Through hole with depth d = 50mm Wet cutting

この試験で得られたデータを図14に示す。発明適用品のドリルは、ワークに対する食いつき時の水平分力X、Yが比較品に比べて小さく、その分力の変動も少ない。 The data obtained in this test is shown in FIG. In the drill of the invention application product , the horizontal component forces X and Y at the time of biting against the workpiece are smaller than those of the comparative product, and the fluctuation of the component force is small.

また、送りf=0.10mm/revの条件と、f=0.15mm/revの条件(その他の条件は変化なし)でのドリル径の実測値に対する加工穴の入口径、中間径、出口径の変化状況を調べた。その結果を図15に示す。比較品は送りが変化したときの穴径変動が大きく、送りf=0.15mm/revでの穴出口径の縮小傾向も顕著であるが、発明適用品は送り量が変化しても穴径の変化傾向が安定しており、また、穴出口径の縮小傾向が殆ど生じていない。 In addition, the machining hole inlet diameter, intermediate diameter, and outlet diameter with respect to the actual measured values of the drill diameter under the conditions of feed f = 0.10 mm / rev and f = 0.15 mm / rev (the other conditions remain unchanged). The change situation of was investigated. The result is shown in FIG. The comparative product has a large variation in hole diameter when the feed is changed, and the reduction tendency of the hole outlet diameter at feed f = 0.15 mm / rev is also remarkable, but the invention applied product has a hole diameter even if the feed amount changes. The change tendency is stable, and the hole outlet diameter is hardly reduced.

−実施例3−
実施例2で用いた発明適用品のドリルと比較ドリルを使用して以下の条件で貫通穴の加工を行い、加工された穴の出口側(切り抜け側)におけるばりの発生状況を調べた。
−切削条件−
ワーク材質:SUS304
切削速度V=140m/min
回転数N=1783min−1
送りf=0.10mm/rev及びf=0.15mm/rev
加工穴:深さd=50mmの貫通穴
湿式切削
Example 3
The through hole was machined under the following conditions using the inventive drill and comparative drill used in Example 2, and the occurrence of flash on the exit side (cut-off side) of the machined hole was examined.
-Cutting conditions-
Work material: SUS304
Cutting speed V = 140 m / min
Rotational speed N = 17843 min −1
Feed f = 0.10 mm / rev and f = 0.15 mm / rev
Hole: Through hole with depth d = 50mm Wet cutting

その結果を以下に比較して示す。
送りf=0.10mm/rev時の発生ばり高さ(図19のs1)。発明品ドリル:Max0.80mm、比較ドリル:Max1.20mm
送りf=0.15mm/rev時に発生したばりの高さ。発明品ドリル:Max0.95mm、比較ドリル:Max1.20mm
The results are shown in comparison below.
The generated flash height at feed f = 0.10 mm / rev (s1 in FIG. 19). Invention drill: Max 0.80mm, Comparative drill: Max 1.20mm
The height of the flash generated when the feed f = 0.15 mm / rev. Invention drill: Max 0.95 mm, Comparative drill: Max 1.20 mm

この試験結果から、切れ刃の径方向外端が先に切り抜けるこの発明のドリルは、ばりの抑制効果も得られることがわかる。   From this test result, it can be seen that the drill of the present invention in which the radially outer end of the cutting edge cuts out first can also obtain the effect of suppressing flash.

−実施例4−
ドリル本体の外周に設ける切屑排出用の溝を、ドリル本体の周囲をほぼ1/4周するねじれ溝にして各ねじれ溝の終端側切れ上がり開始点を、前記外周刃から周方向に85〜95°回転した位置に設定したドリルの性能評価試験を行った。その評価試験は、図20に示す、タイプ1〜タイプ5の形状の評価ドリル(ドリル径D=φ20.0mm、L/D=4)を用いて行った。Lは有効長さである。
Example 4
The chip discharging groove provided on the outer periphery of the drill body is a twisted groove that makes a ¼ turn around the periphery of the drill body, and the starting point of the end side of each twisted groove is 85 to 95 in the circumferential direction from the outer peripheral blade. A performance evaluation test of a drill set at a rotated position was performed. The evaluation test was performed using an evaluation drill having a shape of type 1 to type 5 (drill diameter D = φ20.0 mm, L / D = 4) shown in FIG. L is an effective length.

試験は、ドリル本体に負担を与える加工として、いわゆるだるま穴の加工{図21(a)に示すだるま穴の斜線部の加工}と、ワークに対する斜め食い付き加工{図21(b)の45°傾斜の面を有するワークに対する穴加工}を行って、切屑排出用の溝の切れ上がり位置の違いによる加工穴の穴面性状の違いを比較した。
だるま穴加工での加工条件は、ワーク:S50C、切削速度V=130m/min、送りf=0.10mm/rev、湿式切削である。斜め食い付き加工での加工条件も、だるま穴加工での条件と同一とした。
The test is a so-called “dar hole processing” (processing the slanted portion of the dart hole shown in FIG. 21 (a)) and slant biting processing (45 ° in FIG. 21 (b)). Drilling a workpiece having an inclined surface} was performed, and the difference in the hole surface properties of the processed holes due to the difference in the cut-up position of the chip discharging groove was compared.
The machining conditions in the daruma hole machining are: workpiece: S50C, cutting speed V = 130 m / min, feed f = 0.10 mm / rev, wet cutting. The processing conditions in the diagonal biting process were also the same as the conditions in the boring hole process.

だるま穴加工で得られた加工面の写真を図22に、斜め食い付き加工で得られた加工面の写真を図23にそれぞれ示す。タイプ1〜タイプ5の形状のドリルは、だるま穴加工、斜め食い付き加工のどちらにおいても、切削抵抗値の差はほとんど無かったが、加工面の性状はタイプ3のドリルによるものが他のドリルによるものに比べて良好であった。   FIG. 22 shows a photograph of the machined surface obtained by the daruma hole machining, and FIG. 23 shows a photograph of the machined surface obtained by the oblique biting process. The drills of type 1 to type 5 had almost no difference in cutting resistance values in both the drill hole drilling and the diagonal chamfering, but the properties of the machined surface were those of the type 3 drill. It was better than that by.

だるま穴加工では、タイプ4,5のドリルは加工面全体に擦れ痕が発生し、戻りマークも発生している。その原因は、ドリル本体の剛性が弱く、撓みながらの切削がなされたことにあると推測される。タイプ1のドリルは擦れ痕の発生はないが、戻りマークが発生しており、これも撓みながらの切削になったことが原因と推測される。タイプ2、3のドリルは、若干のビビリ痕、擦れ痕が見られるが、全体的には良好レベルの加工面が得られていると言える。   In the dart hole drilling, the type 4 and 5 drills are rubbed on the entire machined surface and have a return mark. The cause is presumed to be that the drill body was weak in rigidity and cut while being bent. The type 1 drill does not generate rubbing marks, but has a return mark, which is also presumed to be caused by cutting while bending. The drills of types 2 and 3 show some chatter marks and scratch marks, but it can be said that a good level of processed surface is obtained as a whole.

斜め食い付き加工では、タイプ1,2,4,5のドリルは加工面全体に擦れ痕が発生し、戻りマークも発生している。その原因は、ドリル本体の剛性が弱く撓みながらの切削になったからであると推測される。タイプ3のドリルは若干の擦れ痕が見られるが、全体的には良好レベルの加工面が得られている。   In the diagonal biting process, the drills of types 1, 2, 4, and 5 have rub marks on the entire processed surface and a return mark. The cause is presumed to be that the drill body was weak and the cutting was performed while bending. The type 3 drill shows a slight rubbing trace, but as a whole, a good level of processed surface is obtained.

発明適用ドリルの一例を示す側面図Side view showing an example of the invention application drill 図1のドリルの180°回転した位置の側面図Side view of the position of the drill of FIG. 1 rotated 180 ° 図1のドリルの正面図Front view of the drill of FIG. 図2のドリル先端側を拡大した側面図Fig. 2 is an enlarged side view of the drill tip side. (a)外周刃とねじれ溝の終端の位置関係を示す正面図、(b)切屑排出用溝の終端を展開して示す断面図(A) Front view showing the positional relationship between the outer peripheral edge and the end of the torsion groove, (b) Cross-sectional view showing the end of the chip discharging groove expanded (a)中心刃と外周刃の軌跡を示す図、(b)ドリル径変更後の中心刃と外周刃の軌跡を示す図(A) The figure which shows the locus | trajectory of a center blade and an outer periphery blade, (b) The figure which shows the locus | trajectory of a center blade and an outer periphery blade after a drill diameter change. 直径18.5mmの試作ドリルのスラストと水平分力の測定結果を示す図The figure which shows the measurement result of thrust and horizontal component force of the trial drill of 18.5mm in diameter 直径20.0mmの試作ドリルのスラストと水平分力の測定結果を示す図The figure which shows the measurement result of thrust and horizontal component force of the trial drill of diameter 20.0mm 直径22.5mmの試作ドリルのスラストと水平分力の測定結果を示す図The figure which shows the measurement result of thrust and horizontal component force of the trial drill of diameter 22.5mm 直径18.5mmの試作ドリルによる加工穴の内径の変化傾向を示す図The figure which shows the change tendency of the internal diameter of the processing hole by the trial drill of diameter 18.5mm 直径20.0mmの試作ドリルによる加工穴の内径の変化傾向を示す図The figure which shows the change tendency of the internal diameter of the processing hole by the trial drill of diameter 20.0mm 直径22.5mmの試作ドリルによる加工穴の内径の変化傾向を示す図The figure which shows the change tendency of the internal diameter of the processing hole by the trial drill of diameter 22.5mm 実施例2で用いた比較ドリルの刃形を示す図The figure which shows the blade shape of the comparative drill used in Example 2 実施例2の試験で得た発明適用ドリルと比較ドリルの水平分力X,Yを比較して示す図The figure which compares and compares horizontal component force X of the invention application drill obtained by the test of Example 2, and a comparison drill, Y 実施例2の試験で得た発明適用ドリルと比較ドリルの加工穴の内径の変化傾向を示す図The figure which shows the change tendency of the internal diameter of the working hole of the invention application drill obtained by the test of Example 2, and a comparative drill 改善対象の従来ドリルの刃形の一例を示す図The figure which shows an example of the blade shape of the conventional drill of the improvement object 改善対象の従来ドリルの刃形の他の例を示す図The figure which shows the other example of the blade shape of the conventional drill of the improvement object 中心刃と外周刃を同一スローアウェイチップで形成する場合の従来ドリルの外径変更方法を示す図The figure which shows the outer diameter change method of the conventional drill when the center blade and the outer peripheral blade are formed with the same throwaway tip 貫通穴加工で出口穴の縁に発生するばりの説明図Explanatory drawing of the burr generated at the edge of the exit hole in through hole processing 実施例4の評価試験に用いたタイプ1〜タイプ5のドリルの形状を示す図The figure which shows the shape of the drill of type 1-type 5 used for the evaluation test of Example 4 (a)実施例4におけるだるま穴加工の説明図、(b)実施例4における斜め食い付き加工の説明図(A) Explanatory drawing of boring hole processing in Example 4, (b) Explanatory drawing of oblique biting processing in Example 4. だるま穴加工で得られた加工面の写真Photograph of machined surface obtained by Daruma hole machining 斜め食い付き加工で得られた加工面の写真Photograph of processed surface obtained by oblique biting process

符号の説明Explanation of symbols

1 ドリル本体
2 切屑排出用の溝
2a 切れ上がり開始点
3 チップ座
4 ランド部
−1,5−2 スローアウェイチップ
6 クランプ穴
7 クランプねじ
8 中心刃
9 外周刃
9a 外端コーナ部
10 ドリル
11 加工穴
12 ばり
1 drill body 2 chip discharge groove 2a Kireagari starting point 3 tip seat 4 land portion 5-1 for, 5-2 indexable 6 clamp holes 7 clamping screw 8 the center cutting edge 9 peripheral cutting edge 9a outer end corner portion 10 drill 11 Drilled hole 12

Claims (2)

ドリル本体(1)の先端のドリル周方向に半周した位置に第1スローアウェイチップ(5−1)と第2スローアウェイチップ(5−2)を回転中心(O)からの設置距離を異ならせて配置し、
ドリル外径側に配置される第2スローアウェイチップ(5−2)をドリル内径側にドリルの回転中心を越えて配置される第1スローアウェイチップ(5−1)よりも軸方向前方に突出させてワークに対する食いつきが第2スローアウェイチップ(5−2)の外端コーナ部(9a)から起こるようにし、さらに、前記第1スローアウェイチップ(5−1)によって形成される中心刃(8)の切削負担量(A)と第2スローアウェイチップ(5−2)によって形成される外周刃(9)の切削負担量(B)の割合をA:B=52:48〜55:45の範囲に設定し、
以上の構成としたスローアウェイドリルの外径を変更する際に、第2スローアウェイチップ(5−2)と第1スローアウェイチップ(5−1)の位置を共に変化させて前記中心刃(8)と外周刃(9)の切削負担量の比率A:B=52:48〜55:45をドリル径変更後も維持するようにしたスローアウェイドリルのチップ配置方法。
The first throw-away tip (5 −1 ) and the second throw-away tip (5 −2 ) are placed at different positions from the center of rotation (O) at a position half the circumference of the drill body (1) in the drill circumferential direction. And place
The second throw-away tip ( 5-2 ) disposed on the outer diameter side of the drill protrudes forward in the axial direction from the first throw-away tip ( 5-1 ) disposed on the inner diameter side of the drill beyond the rotation center of the drill. by as bite the workpiece occurs from the outer end corner of the second indexable insert (5 -2) (9a), further, center cutting edge (8 formed by the first indexable insert (5 -1) ) And the cutting burden amount (B) of the outer peripheral blade (9) formed by the second throw-away tip ( 5-2 ), A: B = 52: 48 to 55:45 Set to range,
When changing the outer diameter of the throw-away drill having the above-described configuration, the positions of the second throw-away tip ( 5-2 ) and the first throw-away tip ( 5-1 ) are changed together to change the center blade (8 ) And the cutting load ratio A: B = 52: 48 to 55:45 of the outer peripheral blade (9) is maintained even after the drill diameter is changed.
ドリル外径を変更する際に、そのドリル外径の変更前後において同一仕様のスローアウェイチップを使用することを特徴とする請求項1に記載のスローアウェイドリルのチップ配置方法。  The throw-away drill tip placement method according to claim 1, wherein when the drill outer diameter is changed, a throw-away tip having the same specification is used before and after the drill outer diameter change.
JP2007098150A 2006-12-25 2007-04-04 Tip placement method for throw-away drills Active JP4976181B2 (en)

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JP2007098150A JP4976181B2 (en) 2006-12-25 2007-04-04 Tip placement method for throw-away drills
PCT/JP2007/074700 WO2008078696A1 (en) 2006-12-25 2007-12-21 Throw-away drill and tip arrangement method for the drill
ES07851052.6T ES2453366T3 (en) 2006-12-25 2007-12-21 Procedure to arrange inserts in a drill
CN2007800451269A CN101547763B (en) 2006-12-25 2007-12-21 Throw-away drill and tip arrangement method for the drill
US12/520,338 US8388278B2 (en) 2006-12-25 2007-12-21 Indexable drill and method for arranging inserts in the drill
EP07851052.6A EP2098319B1 (en) 2006-12-25 2007-12-21 Method for arranging inserts in a drill
IL199432A IL199432A (en) 2006-12-25 2009-06-18 Indexable drill and method for arranging inserts in the drill

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JP2007098150A JP4976181B2 (en) 2006-12-25 2007-04-04 Tip placement method for throw-away drills

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IL199432A (en) 2014-09-30
EP2098319A1 (en) 2009-09-09
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EP2098319B1 (en) 2014-02-12

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